A Novel Device To Improve Renal Blood Flow In Cardiorenal Syndrome
Funder
National Health and Medical Research Council
Funding Amount
$198,900.00
Summary
The aim of this project is to assist in the development of a novel device to treat poor delivery of blood to the kidneys in conditions such as heart muscle weakness (chronic heart failure, CHF). Specifically we aim to build a prototype and test the device in a relevant animal model of CHF. Chronic heart failure is a major public health problem affecting >10% of the adult population over the age of 60 years. It is associated with high morbidity, mortality, frequent hospitalisation and major co ....The aim of this project is to assist in the development of a novel device to treat poor delivery of blood to the kidneys in conditions such as heart muscle weakness (chronic heart failure, CHF). Specifically we aim to build a prototype and test the device in a relevant animal model of CHF. Chronic heart failure is a major public health problem affecting >10% of the adult population over the age of 60 years. It is associated with high morbidity, mortality, frequent hospitalisation and major cost burden on the public health system. Weak heart muscle results in poor delivery of blood to the kidneys. Poor delivery to the kidneys activates circulating hormones which in turn further impair cardiac function by adverse effects on the heart. We have developed and patented a novel catheter based system for improvement of renal function via a purpose built device. Proof-of-concept studies have shown that the device should improve kidney blood flow in the setting of CHF. Given the huge public health problem of heart failure and the importance of the kidney in this setting, the commercial potential for a simple device that can be positioned via a catheter-based approach, permanently implanted is large. The device is currently being constructed by the Monash University Department of Engineering where expertise exists with regard to biomedical devices and materials engineering. A series of proof-of-concept studies will then be performed in sheep, as the vasculature of the sheep roughly approximates the dimensions of man. Sheep with CHF will have the device inserted percutaneously into the aorta. Measurements will be made of renal artery flow, relevant circulatory hormones and ultrasound of the heart at baseline (pre-deployment) and following deployment. We believe the above studies (should they be successful) will be sufficient to constitute definitive proof-of-concept and thus allow the device to be commercialised, most likely by a licensing arrangement with a device company.Read moreRead less
Dynamic In Vivo Size & Shape Measurement Of The Human Upper Airway Using Endoscopic Long-range Optical Coherence Tomogra
Funder
National Health and Medical Research Council
Funding Amount
$184,250.00
Summary
This project will fund the construction of a clinically deployable prototype device to measure changes in upper airway size and shape in patients with obstructive sleep apnoea. We have recently developed and validated a technique based on endoscopic optical coherence tomography (OCT). Preliminary in vivo studies have been performed in the human upper airway and the results published. To our knowledge, this is the only such system world-wide capable of making these important measurements. The tec ....This project will fund the construction of a clinically deployable prototype device to measure changes in upper airway size and shape in patients with obstructive sleep apnoea. We have recently developed and validated a technique based on endoscopic optical coherence tomography (OCT). Preliminary in vivo studies have been performed in the human upper airway and the results published. To our knowledge, this is the only such system world-wide capable of making these important measurements. The technique has wide commercially applicability as it can be used to measure the internal dimensions of any hollow organ system.Read moreRead less
Development Of Quantitative Tools For Assessment Of Regional Cardiac Function By Echocardiography
Funder
National Health and Medical Research Council
Funding Amount
$209,430.00
Summary
The application of ultrasound imaging to the assessment of cardiac function (echocardiography) is an invaluable tool for the assessment of patients with known or suspected cardiac problems. The assessment of contraction in each region of the heart is probably the most important of the reasons for doing this test, as regional function is disturbed in patients with coronary artery disease, which is one of the most common causes of death in Australia. The problem is that this analysis is currently ....The application of ultrasound imaging to the assessment of cardiac function (echocardiography) is an invaluable tool for the assessment of patients with known or suspected cardiac problems. The assessment of contraction in each region of the heart is probably the most important of the reasons for doing this test, as regional function is disturbed in patients with coronary artery disease, which is one of the most common causes of death in Australia. The problem is that this analysis is currently completely subjective, and the reliability of the tool is based upon the availability of an experienced observer. This is particularly a problem in rural Australia, as most specialists with expertise in this modality work in the capital cities, and especially a problem in Queensland, where fewer than half of the population live in the capital. The cardiac imaging group at the University of Queensland have been working in collaboration with GE-Vingmed Ultrasound to develop a quantitative technique for the assessment of regional cardiac function since 1997. This collaboration has been the source of a number of published papers and presentations at international meetings. Our group is considered to be a world leader in the field and our industry partner is clearly the most focused of its competitors in addressing this problem. This submission seeks to address several remaining problems. The data thus far addressed function during stress, when the condition of most patients is similar. Tissue velocities are more variable at rest, and a more sophisticated approach is required to accurately measure the lower velocities in the resting state. This research plan seeks support for the development of a new, high frame-rate acquisition that would facilitate the examination of velocities relative to each other, so that translational motion of the heart does not influence the reading. This new method would then be validated against other techniques for assessing function and disease.Read moreRead less
Novel Nanoparticle Composites For Molecular Probes In Diagnostic Imaging
Funder
National Health and Medical Research Council
Funding Amount
$170,716.00
Summary
Isotope labelled protein probes, eg. antibodies, are a valuable imaging tool in investigating patient disease. Their biological specificity is their great strength, however, detection sensitivity often limits their use. A novel nanoparticle developed at ANU can increase this signal by a million-fold in comparison with conventional methods of labelling. This approach suits a range of probes and will accommodate many of the isotopes already used in patient diagnostics and therapy.